9 Declarations [dcl.dcl]

A placeholder-type-specifier designates a placeholder type that will be replaced later by deduction from an initializer.

A placeholder-type-specifier of the form type-constraint${}_{opt}$ auto can be used as a decl-specifier of the decl-specifier-seq of a parameter-declaration of a function declaration or lambda-expression and, if it is not the auto type-specifier introducing a trailing-return-type (see below), is a generic parameter type placeholder of the function declaration or lambda-expression.

A placeholder type can appear with a function declarator in the decl-specifier-seq, type-specifier-seq, conversion-function-id, or trailing-return-type, in any context where such a declarator is valid.

If the function declarator includes a trailing-return-type ([dcl.fct]), that trailing-return-type specifies the declared return type of the function.

Otherwise, the function declarator shall declare a function.

If the declared return type of the function contains a placeholder type, the return type of the function is deduced from non-discarded return statements, if any, in the body of the function ([stmt.if]).

The type of a variable declared using a placeholder type is deduced from its initializer.

This use is allowed in an initializing declaration ([dcl.init]) of a variable.

The placeholder type shall appear as one of the decl-specifiers in the decl-specifier-seq and the decl-specifier-seq shall be followed by one or more declarators, each of which shall be followed by a non-empty initializer.

The auto type-specifier can also be used to introduce a structured binding declaration ([dcl.struct.bind]).

A placeholder type can also be used in the type-specifier-seq in the new-type-id or type-id of a new-expression ([expr.new]) and as a decl-specifier of the parameter-declaration's decl-specifier-seq in a template-parameter ([temp.param]).

The auto type-specifier can also be used as the simple-type-specifier in an explicit type conversion (functional notation) ([expr.type.conv]).

A program that uses a placeholder type in a context not explicitly allowed in [dcl.spec.auto] is ill-formed.

If the init-declarator-list contains more than one init-declarator, they shall all form declarations of variables.

The type of each declared variable is determined by placeholder type deduction, and if the type that replaces the placeholder type is not the same in each deduction, the program is ill-formed.

If a function with a declared return type that contains a placeholder type has multiple non-discarded return statements, the return type is deduced for each such return statement.

If the type deduced is not the same in each deduction, the program is ill-formed.

If a function with a declared return type that uses a placeholder type has no non-discarded return statements, the return type is deduced as though from a return statement with no operand at the closing brace of the function body.

An exported function with a declared return type that uses a placeholder type shall be defined in the translation unit containing its exported declaration, outside the private-module-fragment (if any).

If a variable or function with an undeduced placeholder type is named by an expression ([basic.def.odr]), the program is ill-formed.

Once a non-discarded return statement has been seen in a function, however, the return type deduced from that statement can be used in the rest of the function, including in other return statements.

Return type deduction for a templated function with a placeholder in its declared type occurs when the definition is instantiated even if the function body contains a return statement with a non-type-dependent operand.

If a function or function template F has a declared return type that uses a placeholder type, redeclarations or specializations of F shall use that placeholder type, not a deduced type; otherwise, they shall not use a placeholder type.

A function declared with a return type that uses a placeholder type shall not be virtual ([class.virtual]).

A function declared with a return type that uses a placeholder type shall not be a coroutine ([dcl.fct.def.coroutine]).

An explicit instantiation declaration does not cause the instantiation of an entity declared using a placeholder type, but it also does not prevent that entity from being instantiated as needed to determine its type.

Placeholder type deduction is the process by which a type containing a placeholder type is replaced by a deduced type.

A type T containing a placeholder type, and a corresponding initializer-clause E, are determined as follows:

• (2.1)
  For a non-discarded return statement that occurs in a function declared with a return type that contains a placeholder type, T is the declared return type.

  • (2.1.1)
    If the return statement has no operand, then E is void().
  • (2.1.2)
    If the operand is a braced-init-list ([dcl.init.list]), the program is ill-formed.
  • (2.1.3)
    If the operand is an expression X that is not an assignment-expression, E is (X).

    [Note 1: 

    A comma expression ([expr.comma]) is not an assignment-expression.

    — end note]
  • (2.1.4)
    Otherwise, E is the operand of the return statement.

  If E has type void, T shall be either type-constraint${}_{opt}$ decltype(auto) or cv type-constraint${}_{opt}$ auto.
• (2.2)
  For a variable declared with a type that contains a placeholder type, T is the declared type of the variable.

  • (2.2.1)
    If the initializer of the variable is a brace-or-equal-initializer of the form = initializer-clause, E is the initializer-clause.
  • (2.2.2)
    If the initializer is a braced-init-list, it shall consist of a single brace-enclosed assignment-expression and E is the assignment-expression.
  • (2.2.3)
    If the initializer is a parenthesized expression-list, the expression-list shall be a single assignment-expression and E is the assignment-expression.
• (2.3)
  For an explicit type conversion ([expr.type.conv]), T is the specified type, which shall be auto.

  • (2.3.1)
    If the initializer is a braced-init-list, it shall consist of a single brace-enclosed assignment-expression and E is the assignment-expression.
  • (2.3.2)
    If the initializer is a parenthesized expression-list, the expression-list shall be a single assignment-expression and E is the assignment-expression.
• (2.4)
  For a non-type template parameter declared with a type that contains a placeholder type, T is the declared type of the non-type template parameter and E is the corresponding template argument.

T shall not be an array type.

If the placeholder-type-specifier is of the form type-constraint${}_{opt}$ auto, the deduced type $T^{\prime }$ replacing T is determined using the rules for template argument deduction.

If the initialization is copy-list-initialization, a declaration of std​::​initializer_list shall precede ([basic.lookup.general]) the placeholder-type-specifier.

Obtain P from T by replacing the occurrences of type-constraint${}_{opt}$ auto either with a new invented type template parameter U or, if the initialization is copy-list-initialization, with std​::​initializer_list<U>.

Deduce a value for U using the rules of template argument deduction from a function call, where P is a function template parameter type and the corresponding argument is E.

If the deduction fails, the declaration is ill-formed.

Otherwise, $T^{\prime }$ is obtained by substituting the deduced U into P.

If the placeholder-type-specifier is of the form type-constraint${}_{opt}$ decltype(auto), T shall be the placeholder alone.

The type deduced for T is determined as described in [dcl.type.decltype], as though E had been the operand of the decltype.

For a placeholder-type-specifier with a type-constraint, the immediately-declared constraint ([temp.param]) of the type-constraint for the type deduced for the placeholder shall be satisfied.